Influence of compaction on small-strain shear modulus of iron ore tailings

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2022-01-17 DOI:10.1680/jgeen.21.00036
J. P. Silva, P. Cacciari, L. F. Ribeiro, M. Jefferies
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引用次数: 1

Abstract

Understanding the geotechnical properties of iron ore tailings is one of the biggest challenges that the mining industry currently faces. The brittle behaviour of these tailings has brought the importance of small strain stiffness to the geotechnical forefront. However, lack of knowledge and information about the behaviour of iron ore tailings still exists. This paper presents the results and analysis of a laboratory program that aimed to assess the small strain stiffness of tailings materials. These materials were produced during the iron ore treatment process. Bender elements were used to measure shear wave velocities and evaluate dynamic shear moduli at different effective stress levels resulting from isotropic consolidation tests. Three types of iron ore tailings were used: (1) flotation, (2) slimes, and (3) blended with different grain-size distributions. Reconstituted specimens were prepared at different densities (loose and dense conditions) to assess initial density effects (percent compaction) upon the shear modulus. The laboratory results were compared with empirical correlations with other soil types. Nevertheless, these equations were ineffective in representing tailings materials that contain large amounts of fines (slimes). The advantages and limitations of these equations are discussed, and a new empirical equation that includes the degree of compaction is suggested.
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压实对铁矿尾矿小应变剪切模量的影响
了解铁矿尾矿的岩土力学特性是目前矿业面临的最大挑战之一。这些尾矿的脆性特性使小应变刚度的重要性上升到岩土工程的前沿。然而,对铁矿尾矿特性的认识和信息仍然缺乏。本文介绍了尾矿材料小应变刚度试验程序的结果和分析。这些材料是在铁矿处理过程中产生的。本德尔单元用于测量剪切波速,并评估由各向同性固结试验产生的不同有效应力水平下的动态剪切模量。采用3种不同类型的铁矿尾矿:(1)浮选尾矿,(2)泥尾矿,(3)不同粒度分布的混配尾矿。在不同密度(松散和致密条件)下制备重建试样,以评估初始密度对剪切模量的影响(压实百分比)。将实验室结果与其他土壤类型的经验相关性进行了比较。然而,这些方程对于含有大量细粒(泥)的尾矿材料是无效的。讨论了这些方程的优点和局限性,并提出了一个新的包含压实度的经验方程。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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